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Arbor Acres Investigating Hatchery Practice PDF

48 Pages·2011·0.65 MB·English
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October 2009 update Investigating Hatchery Practice Dr. Steve Tullett Investigating Hatchery Practice: About the Author Aviagen provides customers with detailed product Performance Specifications, Management Manuals and Nutrition Specifications as a basis for managing their flocks. This document, produced by Aviagen’s Technical Transfer Department, is one of an ongoing series of Arbor Acres Update. The Arbor Acres Update covering hatchery practices focus on the topic of hatchery monitoring and management. They give background and practical details on aspects of hatchery and incubation practice, and aim to improve understanding of the principles of successful hatchery management for good hatchability and chick quality. Good practice in egg and hatchery management will maximize the hatchability of eggs produced by a flock, and will ensure good chick quality and the best possible start for good performance of the progeny. The principles described here have a broad relevance to most regions and production strategies. About the Author - Steve Tullett Dr Steve Tullett is a Consultant for Aviagen specializing in incubation and fertility. Steve is a graduate from the University of Bath, England, where he received his BSc and PhD degrees. He spent ten years at the AFRC’s Poultry Research Centre, now the Roslin Institute, near Edinburgh, Scotland, where he conducted studies in energy metabolism, incubation physiology and egg quality. He then became senior lecturer in the Poultry Science Department at the Scottish Agricultural College, Auchincruive. After this, he joined Bernard Matthews Foods Ltd with responsibility for advice on turkey and chicken production in England and Hungary. He joined Ross Breeders (now part of Aviagen) in Edinburgh as Worldwide Technical Services Co-ordinator. Later he rejoined Bernard Matthews Foods Ltd as their Research Manager, where he had special responsibility for technical matters in Europe and Asia. Steve then took the position of Technical Director for Anitox, a worldwide supplier of bacterial and mould control products for the animal feed industry. In March 2006, Steve founded Cornerways Poultry Consultants Ltd. His 30 years of experience in the poultry industry and colleague network enables him to provide technical inputs into many aspects of poultry production around the world. Steve has published over 40 scientific research papers and book chapters, reviews poultry papers and books for scientific journals and is a regular presenter at many seminars and conferences. October 2009 2 Investigating Hatchery Practice: Contents Contents 04 Introduction 06 Assessing Fertility 12 Examining the Hatch Debris 16 Monitoring Egg and Chick Weights 18 Monitoring Temperatures 19 Monitoring the Hatch Window 21 Routine Quality Control in the Hatchery and the Recording and Analysis of Results 28 Interpretation of Results 31 Effects of Nutrition on Infertility, Embryo Mortality and Hatchability 33 Appendices 33 Appendix 1: Some Rules of Egg Collection 34 Appendix 2: Some Rules of Egg Selection 35 Appendix 3: Some Rules of Egg Disinfection 36 Appendix 4: Some Rules of Fumigation 37 Appendix 5: Some Rules of Egg Storage 38 Appendix 6: Dew Point or Condensation Table 39 Appendix 7: Some Suggestions for Hatchery Recording Forms Executive Summary In this document the biological targets which need to be met in the chicken hatchery to ensure good hatchability and chick quality, and how to assess, measure and incorporate these into routine quality control programmes are described. Several traits should be recorded and monitored on an ongoing basis within the hatchery, including fertility (a number of different ways to identify infertile eggs are described) and embryonic mortality patterns. Accurate identification of fertility is important if the appropriate corrective action is to be taken when candling clears are high. The pattern of embryonic mortality and the identification of certain abnormalities and malpositions will provide an indication of when incubation conditions are inappropriate. Targets for these traits are given for different flock ages for both detailed and simplified break-outs. The document also covers methods for monitoring egg weight loss to transfer and chick yields at take-off, which should be around 12% and 67% of the fresh egg weight respectively. Monitoring egg surface temperatures is also important as this will show when the eggs come up to temperature too slowly (increasing early dead mortality) and if they become overheated in the later stages of incubation (increasing late mortality and culls). Monitoring egg surface temperatures will also provide useful information for changes in future incubation temperature programmes. Regular monitoring of the biological outcomes of incubation is vital for identifying when incubation conditions are below optimal and in determining what needs to be changed in order to improve hatchability. October 2009 3 Introduction To achieve good hatchability and chick quality, fertile eggs need careful management from the time they are laid. Environmental conditions during egg collection, egg shell disinfection, transport, pre-storage incubation, storage, pre-warming or during incubation are all important. Inappropriate treatment can result in depressed hatchability, change the pattern of embryo mortality and may also affect post-hatching performance. The investigative procedures described in this Arbor Acres Update can be used in the routine quality control programme in the hatchery to benchmark hatchability levels and the nature of embryo losses against accepted best practice standards. Other information is provided that may be useful when troubleshooting hatchery problems. Routine Quality Control in the Hatchery Not all fertile eggs hatch. Even eggs from flocks which are hatching well follow a predictable embryonic mortality pattern. Mortality is usually higher in the first few days of incubation when all the organ systems are forming in the embryo. The middle period of incubation is essentially a period of rapid growth and is usually characterised by very few embryo deaths. Mortality rises again in the last few days of incubation when the embryos turn towards the air cell in order to ventilate their lungs, redirect their blood circulation, retract their yolk sacs and finally attempt to hatch. Figure 1 shows a normal pattern of mortality in a flock which is hatching well. Figure 1: Normal pattern of embryo losses during incubation. Based on Kuurman et al. (2003). Poultry Science, 82:214-222 0.25 s o y r 0.2 b m E g 0.15 n si o L f o 0.1 y t bili a 0.05 b o r P 0 0 3 6 9 12 15 18 21 Days of Incubation October 2009 4 Investigating Hatchery Practice: Introduction Gathering data on fertility, hatchability and the time and nature of embryo losses relative to flock age is an important part of the routine quality control programme in any hatchery. Hatchery workers should be trained to gather the relevant data. They need to know how to recognize infertility and egg contamination, and to identify the stage of development reached by embryos that failed to hatch. They also need to recognize embryonic malformations and malpositions. Accurate data allows hatchery performance to be compared against best practice standards and provides the baseline for investigating hatchability problems when they arise. By establishing where deviations from the normal pattern of embryonic mortalities are occurring, it is usually possible to identify where the problem lies. For example: • Losses in the first week of incubation tend to be due to problems arising before incubation (i.e. on farm, in transport or in storage). • Losses in the second week of incubation are most likely to arise from contamination or faults in nutrition, although occasionally inappropriate setter conditions may be involved. • Losses in the final week of incubation are usually associated with inappropriate incubator conditions. Procedures for Monitoring Hatchery Performance Procedures and skills that can be used in routine hatchery quality control, when carrying out a hatchery investigation and when troubleshooting hatchability problems include: • Assessing fertility - breaking out fresh unincubated eggs - breaking out partially incubated eggs - breaking out incubator “clears” • Examining the hatch debris - recognizing developmental stages and malformations - recognizing the normal hatching position and malpositions - recognizing egg contamination • Monitoring weight loss during incubation - egg weight loss to 18 days - chick yield • Monitoring temperatures - monitoring the temperature exposure profiles of eggs - measuring eggshell temperatures during incubation • Monitoring the hatch window October 2009 5 Assessing Fertility Breaking Out Fresh Unincubated Eggs After fertilisation, the egg spends about a day travelling down the oviduct. During this time the number of cells in the blastoderm increases to about 60,000. The characteristic organization of these cells just under the yolk sac membrane makes it possible, with practice, to distinguish between an infertile blastodisc and a fertile blastoderm when breaking out fresh unincubated eggs. The infertile blastodisc is a small dense white area about two mm across (Figure 2). The white area is usually of an irregular shape and is never perfectly round. It is surrounded by a clear, roughly circular area up to four mm in diameter which appears to be filled with bubbles, which are in fact globules of yolk (Figure 3). Figure 2: A fresh unincubated infertile egg as Figure 3: Magnified blastodisc of a fresh unincubated it appears to the naked eye infertile egg The fertile blastoderm, by contrast, is larger (4-5 mm diameter) than the dense white area of the infertile blastodisc and is always uniformly round (Figure 4). The usual form is that of a white ring or “doughnut” with a clear centre (Figure 5). In some eggs there may be a small white spot in the centre of the ring. Occasionally eggs are seen which were laid with the blastoderm at an earlier stage of development, when it will appear as a solid white, perfectly round disc. Figure 4: A fresh unincubated fertile egg Figure 5: Magnified blastoderm of a fresh unincubated as it appears to the naked eye fertile egg showing organized ring structure October 2009 6 Investigating Hatchery Practice: Assessing Fertility Natural variation in appearance occurs within each category and undue emphasis should not be given to small differences. It is important to practice recognizing fertility in fresh eggs, initially by using eggs from flocks known to have a highly fertility status and infertile eggs from a commercial table egg laying flock. Eggs should be opened by removing the shell over the air cell and then gently peeling back the inner shell membrane in order to remove it from the surface of the albumen. If the dense bright white area characteristic of the infertile egg or the white “doughnut” characteristic of the fertile egg cannot be clearly seen then the contents of the eggs should be tipped into one hand and the yolk gently rolled over until either the blastodisc or blastoderm is definitely observed (Figure 6). At least one hundred eggs per flock should be examined. The technique is useful because it can give a rapid indication of true flock infertility levels in order to guide breeder management decisions. The technique requires the destruction of hatching eggs. Testing reject eggs is an alternative, but this tends to underestimate true fertility. Figure 6: You may have to remove the egg contents and roll the yolk in your hands in order to locate the blastodisc (infertile) or blastoderm (fertile) in fresh unincubated eggs The internal examination of fresh unincubated eggs will also allow the identification of any abnormalities. For example, mottling of the egg yolk is a disturbance of the vitelline membrane usually caused by stress in the parent hens. Stressors include handling (e.g. for blood sampling), changes in routine and overmating. Feed containing Nicarbazin or mycotoxins can also result in high levels of mottling. Mottling of the yolk may cause elevated numbers of early dead embryos and appears to make the eggs more susceptible to bacterial contamination. Figure 7 shows a fresh egg affected by pronounced mottling. Figure 7: Fresh egg yolk affected by pronounced yolk mottling Thin watery albumen (e.g. due to Infectious Bronchitis or prolonged egg storage) will also reduce hatchability. Cotton and Kapok seed meal as a contaminant of feed can cause the egg yolk to become thick and viscous (rubbery) and will also reduce hatchability. An example form for recording the breakout of fresh unincubated eggs is given in Appendix 7 (Form 1). October 2009 7 Breaking Out Partially Incubated Eggs Breaking Out Fresh Unincubated Eggs The fertility test undertaken on partially incubated eggs requires the destruction of some hatching eggs, but is easier and requires considerably less practice than examining fertility in fresh unincubated eggs. Once again, a 100-egg sample per flock is the minimum requirement, although it is usually more practical to use one or more full setter trays. Eggs should have been incubated for 3-5 days prior to examination. Each egg should be opened very carefully from the top of the air cell so as to avoid any disruption to the egg contents, then the blastoderm or infertile disc will be on the upper surface of the yolk and very easy to see. Do not spend too much time trying to identify signs of membrane development - if it is not obvious it has not happened. A truly infertile egg will have the characteristic small dense white area described previously for fresh unincubated eggs. Embryos dying in the first and second day of incubation will show development of extra-embryonic membrane growth over the top of the yolk. This is characterised by a cream colored disc much larger than the white doughnut in the fresh unincubated fertile egg. After one day of incubation, the area occupied by the extra-embryonic membranes will be about one centimetre in diameter (Figure 8), whilst after two days the membranes will occupy almost the entire upper surface of the yolk (Figure 9). Figure 8: Embryo after one day in the setter Figure 9: Embryo after two days in the setter After three days of incubation, live embryos will have well developed circulatory systems (see Figure 10). Figure 10: Embryo at the “Blood Ring” stage October 2009 8 Investigating Hatchery Practice: Assessing Fertility On days three and four of incubation the inner shell membrane looks white when the shell above the air cell is removed. This is due to a drying process as water moves from the albumen into the yolk to form the sub-embryonic fluid. The sub-embryonic fluid is milky and sits on top of the yolk, giving the yolk a paler and more watery appearance than in the earlier stages of development or in the fresh egg. From day five onwards, the characteristic feature of the embryo is the black pigmented eye (Figure 11). The term “Black Eye” has been used to describe the embryo from day five to day 12 of incubation, after which time there is the obvious development of feathers. Figure 11: Embryo at the “Black Eye” stage. Note the early development of the wings and legs at this stage An example form for recording the breakout of partially incubated eggs is given in Appendix 7 (Form 2). Normal Early Embryonic Development The embryonic development which occurs whilst the egg is still inside the hen simplifies identification of infertility prior to incubation. An unfertilised germinal disc will show little evidence of any structure except for a condensed white spot of variable shape (Figures 2 and 3). A fertilised blastoderm has a pronounced ring or “doughnut” appearance (Figures 4 and 5). The difference is visible to the naked eye even when unmagnified. After one day’s growth, there will be a ring of cream colored membranes measuring about one centimetre in diameter. (Figure 8). After two days of incubation, the cream colored membranes will cover most of the top surface of the yolk. (Figure 9). By day three there will be a well developed circulation system (Figure 10). October 2009 9 Breaking Out Incubator “Clears” Incubator “clears” are those eggs in which no obvious development is seen when a bright light is shone through the eggs in the process known as candling (Figure 12). The term is often, but incorrectly, used as being identical to infertile. Figure 12: Candling table. The infertile eggs and those dying early in incubation show up as the brighter “clear” eggs Depending on the quality of the candling lamp or table and the pigmentation of the shell, incubator “clears” can be candled out from as early as four or five days of incubation. For the brown-shelled eggs of broiler breeders, candling the eggs at eight to 10 days of incubation is usually straight-forward and allows for single-stage incubators to be run sealed up until the time of this candling procedure. Figure 13: “Clear” eggs identified using a candling lamp; no development on left, “Blood Ring” mortality on right “Blood Ring” October 2009 10

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Good practice in egg and hatchery management will maximize the . On days three and four of incubation the inner shell membrane looks white when
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